36 Thornwood Drive APPROVED BY DATE Ithaca, New York 14850 PROD. MGR. Scott Miller 4/25/06 Tel: 607-257-1080 MEMS MGR. Scott Miller 4/25/06 Fax: 607-257-1146 ASIC MGR. Jim Groves 7/12/05 www.kionix.com VP ENG. Tim Davis 7/12/05 info@kionix.com VP SALES Bruce Finke 7/12/05 ECN # REV PG # REVISION DESCRIPTION DATE REV'D BY 05-027 1 5 Added Test Specification 7/12/05 Scott Miller 06-004 2 Updated specification to new format 3/23/06 A. Bergstrom, S. Miller "Kionix" is a registered trademark of Kionix, Inc. Products described herein are protected by patents issued or pending. No license is granted by implication or otherwise under any patent or other rights of Kionix. The information contained herein is believed to be accurate and reliable but is not guaranteed. Kionix does not assume responsibility for its use or distribution. Kionix also reserves the right to change product specifications or discontinue this product at any time without prior notice. This publication supersedes and replaces all information previously supplied. 2006 Kionix, Inc. All rights reserved Page 1 of 8
Product Description The is a three axis, analog output silicon micromachined accelerometer with a fullscale output range of ±2.0g (19.6 m/s 2 ). Plasma micromachining is used to fabricate the sense element using Kionix s proprietary deep reactive ion etch processes. Kionix linear accelerometers function on the principle of differential capacitance; acceleration causes displacement of a silicon structure resulting in a capacitance change. Common mode cancellation is used to decrease errors from process variation, temperature, and environmental stress. The sense element is hermetically sealed at the wafer level by bonding a silicon lid wafer to the device using glass frit. A separate ASIC device packaged with the sense element provides signal conditioning and self-test. The accelerometer is delivered in a 5 x 5 x 1.8 mm Dual Flat No-lead (DFN) package. Functional Diagram X Sensor Charge Amplifier 32K Output X 2 Self Test 10 Oscillator C 2 Y Sensor Charge Amplifier 32K Output Y 13 C 3 Z Sensor Charge Amplifier 32K Output Z 14 Vdd 8 C 4 GND 12 GND 3 Logic 9 PS 5 Parity 4 6 7 11 Res erv ed Res erv ed Res erv ed Res erv ed Page 2 of 8
Product Table 1. Mechanical (specifications are for operation at V dd = 3.3V and T = 25ºC unless stated otherwise) Parameters Units Min Target Max Operating Temperature Range ºC -40-85 Zero-g Offset V 1.617 1.650 1.683 Zero-g Offset Variation from RT over Temp. mg -150-150 Sensitivity mv/g 653 660 667 Sensitivity Variation from RT over Temp. % -2 0 +2 Offset Ratiometric Error (V dd = 3.3V ±5%) % - 0.4 1.5 Sensitivity Ratiometric Error (V dd = 3.3V ±5%) % - 0.4 1.5 Non-Linearity % of FS - 0.1 0.5 Cross Axis Sensitivity % - 2.0 3.0 Self Test Output change on Activation g 1.0 (xy) 1.1 (xy) 1.2 (xy) 0.2 (z) 0.4 (z) 0.6 (z) Bandwidth (-3dB) 1 Hz - - 3100 (XY) 1300 (Z) Noise Density (on filter pins) µg / Hz - 35 (xy) 65 (z) 100 Notes: 1. User definable with external capacitors. Maximum defined by the frequency response of the sensors. Table 2. Electrical (specifications are for operation at V dd = 3.3V and T = 25ºC unless stated otherwise) Parameters Units Min Target Max Supply Voltage (V dd) Operating V 2.5 3.3 5.5 Operating 1 ma 1.3 1.7 2.3 Current Consumption Standby µa - - 10 Analog Output Resistance(R out) kω 24 32 40 Power Up Time 1 ms 5*R out*c Notes: 1. Power up time is determined by 5 times the RC time constant of the user defined low pass filter. Page 3 of 8
Table 3. Environmental Parameters Units Min Target Max Supply Voltage (V dd) Absolute Limits V -0.3-7.0 Operating Temperature Range ºC -40-85 Storage Temperature Range ºC -55-150 Mech. Shock (powered and unpowered) g - - 4600 for 0.5ms ESD HBM V - - 3000 Caution: ESD Sensitive and Mechanical Shock Sensitive Component, improper handling can cause permanent damage to the device. The 14-pin DFN package conforms to European Union Directive 2002/95/EC on the restriction of the use of certain hazardous substances in electrical and electronic equipment (RoHS). Page 4 of 8
Application Schematic and Pin Function Table 1 14 2 13 3 12 C 2 4 11 C 3 5 6 7 KXM52 10 9 8 C 4 Vdd C 1 Page 5 of 8 Table 4. KXM52 Pin Descriptions Pin Name Description 1 NC Not Connected Internally. 2 X Output Analog output of the x-channel. Optionally, a capacitor (C 2) placed between this pin and ground will form a low pass filter. 3 GND Ground 4 Reserved Factory reserved. Connect this pin to ground. 5 Parity Checks EEPROM for parity error. 6 Reserved Factory reserved. Connect this pin to ground. 7 Reserved Factory reserved. Connect this pin to ground. 8 Vdd The power supply input. Decouple this pin to ground with a 0.1uF ceramic capacitor (C 1). 9 When the PS pin is connected to GND or left floating, the KXM52 is shutdown and drawing very little power. When the PS PS pin is tied to Vdd, the unit is fully functional. 10 Self Test. Output X, Output Y, and Output Z of a properly functioning part will increase when Vdd is applied to the self test ST pin. 11 Reserved Factory reserved. Connect this pin to ground. 12 GND Ground 13 Y Output Analog output of y-channel. Optionally, a capacitor (C 3) placed between this pin and ground will form a low pass filter. 14 Z Output Analog output of z-channel. Optionally, a capacitor (C 4)placed between this pin and ground will form a low pass filter. Application Design Equations The bandwidth is determined by the filter capacitors connected from pins 2, 13 and 14 to ground. The response is single pole. Given a desired bandwidth, f BW, the filter capacitors are determined by: C 2 = C 3 = C 4 4.97x10 = f BW 6
Test Parameters Specification Test Conditions Zero-g Offset @ RT 1.650 ± 0.033 V 25ºC, V dd = 3.3V Sensitivity @ RT 660 ± 7 mv/g 25ºC, V dd = 3.3V Cross Axis Sensitivity < 3% 25ºC, V dd = 3.3V Current Consumption Operating 1.3 <= I dd <= 2.0 ma 25ºC, V dd = 3.3V Page 6 of 8
Package Dimensions Page 7 of 8
Package Orientation +Y +X +Z +Z +X Page 8 of 8